DE112007003602T5 - Backup Row Allocation Device, Memory Repair Device, Backup Array Allocation Method, Memory Manufacturing Method, and Program - Google Patents

Abstract

A backup row allocation device that determines which fail rows from the row-oriented fail rows and the column-oriented fail rows contain fail bits in a memory having a plurality of backup rows to associate the backup rows with :
a bit calculation unit that counts, for each fail bit included in each fail row, a number of orthogonal fail bits representing a number of fail bits in a fail row containing each fail bit and having an orientation that deviates from the orientation of each fail row and storing the number of orthogonal fail bits associated with each fail bit;
a weighting calculation unit that calculates a weighting coefficient for each fail series based on the number of orthogonal fail bits of the fail bits included in each fail row and stores the weighting coefficient that accumulates with each fail Row is linked; and
a commit unit that determines to which fail rows the backup rows should be assigned based on the relative size of the weighting coefficients computed by the weighting computation unit.

Description

Technical environment

The The present invention relates to a backup row allocation device, a memory repair device, a backup-row allocation method, a memory manufacturing process and a program. Especially The present invention relates to a backup row allocation device. which determines which rows in a store have failed backup rows have assigned, such as a semiconductor memory, the is designed with a variety of backup rows.

State of the art

One conventional semiconductor memory consists of memory cells, which are arranged in a two-dimensional matrix. In the production of such Semiconductor memory, the memory is desirable configured such that all memory cells function properly. However, because new semiconductor memory has an extremely large number have memory cells, it is difficult to take care to bear that all cells are working properly.

One known method for dealing with this problem involves the semiconductor memories having a fixed number of rows of backup rows of addresses in the rows and columns of the array of memory cells. In such a semiconductor memory, those address rows having defective memory cells known as "fail bits" are replaced by backup rows to repair a semiconductor memory having defective memory cells, such as the one of FIG Japanese Patent Application No. 2-24899 is known.

Disclosure of the invention

Problems solved by the invention

Indeed There is an upper limit on the number of backup rows that are in a semiconductor spoke can be installed. If therefore the backup rows are not adequate to those address rows, fail bits that are assigned can not all fail bits are repaired. Have newer semiconductor memory an enormous number of address series, and therefore becomes an extreme long time needed to get the appropriate arrangement of backup rows which allows all fail bits to be repaired. Therefore, what is needed is a technique that is efficient Detect arrangement of backup rows that allows all Repair fail bits.

Therefore it is a task for one aspect of the present invention Innovations, a backup row allocation device, a memory repair device, a backup-row allocation method, a memory-manufacturing method and to provide a program that is capable are to overcome the above-mentioned disadvantages of the prior art. The above and other tasks can be combined in the described independent claims become. The dependent claims define others advantageous and exemplary combinations of the herein disclosed Innovations.

Method of solution the problems

According to one In the first embodiment of the present invention, there is a backup row allocation device provided, which determines which fail series, from the row-oriented fail rows and the column-oriented ones Fail-rows contain fail-bits in a memory of a variety Contains backup rows to assign backup rows to them. comprising a bit counting unit for each Fail-bit, which is contained in a fail-row, a number counts on orthogonal fail bits, this is a count on Fail bits in a fail row containing each fail bit and having an orientation different from the orientation of each fail row and stores the number of orthogonal fail bits that associated with each fail bit; a weighting calculation unit, which calculates a weighting coefficient for each fail row, based on the number of orthogonal fail bits of those fail bits, which are included in each fail row, and the weighting coefficients stores associated with each fail series; and an allocation unit that determines which of the fail rows the backup rows are assigned based on the relative Size of the weighting coefficients of the Weight calculation unit were calculated.

According to a second aspect of the present invention, there is provided a memory repair apparatus that repairs fail bits of a memory including a plurality of backup rows, comprising a backup row allocation device that determines which rows of failures from the row-oriented fail-rows and column-oriented fail-rows contain fail bits in memory to allocate the backup rows to them; and a setting unit that determines the linkage in memory determined by the backup row allocation device. The backup row allocation device includes a bit counter that counts a number of orthogonal fail bits for each fail bit included in each fail row, which is the number of fail bits in one Fail row containing each fail bit and having an orientation that deviates from the orientation of each fail row and stores the number of orthogonal fail bits associated with each fail bit; a weighting calculation unit that calculates, for each fail series, a weighting coefficient based on the number of orthogonal fail bits that stores fail bits included in each fail series and the weighting coefficient that corresponds to each fail row is linked; and an allocation unit that determines which of the fail rows to allocate the backup rows based on the relative size of the weighting coefficients calculated by the weighting calculation unit.

According to one Third Embodiment of the present invention will be a backup row allocation method provided to determine which fail series, from the row-oriented fail rows and the column-oriented ones Fail rows, fail bits included, in a memory of a variety Contains backup rows to assign backup rows to them. comprehensive for each fail bit contained in each fail row is, calculating a number of orthogonal fail bits, this is the number of fail bits in a fail row, which is every fail bit contains and has an orientation that depends on the orientation each fail row and the number of orthogonal fail bits stores associated with each fail bit; calculation a weighting coefficient based on each fail series on the number of orthogonal fail bits of those fail bits that in each fail row, and storing the weighting coefficient of associated with each fail series; and determining which the fail rows should be assigned to the backup rows based on the relative size of the weighting coefficients.

According to one Fourth Embodiment of the present invention is a memory manufacturing method provided to make a memory, encompassing the manufacture of memory, a variety of backup series contains; and repairing the memory by determining which fail series from the row-oriented fail series and the column-oriented fail rows Fail rows in the fabricated memory to allocate the backup rows. The repair The memory contains for each fail bit Included in each fail series is counting a number on orthogonal fail bits, this is a number of fail bits in a fail row containing each fail bit and an orientation which deviates from the orientation of each fail series, and Storing the number of orthogonal fail bits associated with each fail bit linked; Calculating a weighting coefficient for each fail row, based on the number of orthogonal ones Fail bits of those fail bits contained in each fail row are, and storing the weighting coefficient with each Fail series is linked; and determining which of the fail rows the backup rows should be assigned based on the relative Size of weighting coefficients.

According to one Fifth embodiment of the present invention is a Program provided, which is a computer Enabled as a backup-row allocator which determines which fail series from the row-oriented Fail Rows and Column-oriented Fail Rows Fail Rows contained in a memory containing a variety of backup rows contains the program to allocate the backup rows enables the computer as a bit counter to act for each fail bit in each fail row contains a number of orthogonal fail bits, this is a number of fail bits in a fail row, each one Contains fail bit and has an orientation of the orientation of each fail row deviates and stores the number orthogonal fail bits associated with each fail bit; a weighting calculation unit having a weighting coefficient calculated for each fail row based on number on orthogonal fail bits, the fail bits in each fail row and stores the weighting coefficient that associated with each fail series; and an allocation unit, which determines which of the fail rows to allocate the backup rows are based on the relative size of the weighting coefficients, calculated by the weighting calculation unit.

The Summary does not necessarily describe all necessary Elements of the embodiments of the present invention. The present The invention may also be a sub-combination of the previously described Be elements. The previously described and other elements and Advantages of the present invention will become apparent from the following Description of the embodiments together with the accompanying Drawings more obvious.

figure description

1 exemplifies a memory test device ( 10 ) for testing a memory ( 40 ), such as a semiconductor memory and a memory repair device ( 20 ) to store fail bits ( 40 ) to repair.

2 shows an exemplary embodiment of a backup row allocation device ( 100 ).

3 shows an example of the memory ( 40 ) concerned fail data.

4 describes an exemplary method for the backup row allocation device ( 100 ).

5 shows another exemplary embodiment of the backup row allocation device (FIG. 100 ).

6 shows an exemplary method for the backup row allocation device ( 100 ) out 5 ,

7 FIG. 12 shows a flow chart for an exemplary flow of the backup row allocation device (FIG. 100 ), in conjunction with the 1 to 6 is described.

8th FIG. 13 is a flow chart for an example method according to the allocation method (S404) for assigning the backup rows as shown in FIG 7 described.

9 shows another example of fail data in memory ( 40 ).

10 shows another exemplary embodiment of the backup row allocation device (FIG. 100 ).

11 shows an exemplary fail data bit field that the isolated fail detection unit ( 150 ) assigned.

12 shows an exemplary embodiment of a part of the repair possibility determination unit ( 140 ).

13 shows an exemplary bit field of the fail bits.

14 FIG. 12 shows a flowchart for an exemplary memory manufacturing method, according to an embodiment of the present invention.

15 shows an example of a hardware configuration of a computer ( 1900 ), according to the present embodiment.

Best method to carry out the invention

following Some embodiments of the present invention will be described. The embodiments do not limit the invention in terms their claims, and all combinations of those described Features in the embodiments are not necessarily essential for the implementation of the invention.

1 shows an exemplary memory test device ( 10 ) to a memory ( 40 ), such as a semiconductor memory, and a memory repair device ( 20 ) to store fail bits ( 40 ) to repair. The memory test device ( 10 ) tests whether each memory cell of the memory under test ( 40 ) functions properly. The memory test device ( 10 ) can the series repair unit ( 20 ) Announce fail data indicating whether each cell of the memory ( 40 ) is a fail bit. The memory ( 40 ) may be a semiconductor memory in which the memory cells are arranged in a two-dimensional matrix. The memory ( 40 ) may be configured with a fixed number of backup rows corresponding to address rows arranged in rows and columns in the matrix of the memory cells.

The memory repair device ( 20 ) is configured with a backup row allocation device ( 100 ) and a fixing unit ( 30 ). The backup row allocation device ( 100 ) receives the memory ( 40 ) fail data from the memory test device ( 10 ). Based on this fail data, the backup row allocation device ( 100 ), to which fail rows the backup rows are assigned, namely from the address rows of the memory ( 40 ) containing fail bits in rows or columns, that is, row-oriented fail rows and column-oriented fail rows. Here, a "fail line" may refer to an address row that contains a fail bit in a row or column. The integration unit ( 30 ) sets the memory bank allocation in memory ( 40 ) generated by the backup row allocation device ( 100 ) is determined. For example, the integration unit ( 30 ) the assignment in memory ( 40 ) by using a laser or the like to control the wiring of the memory ( 40 ) in accordance with the assignment of the backup rows. This procedure allows a memory ( 40 ) in which the fail bits are repaired.

2 shows an exemplary embodiment of the backup row allocation device (FIG. 100 ). The backup row allocation device ( 100 ) contains a bit counting unit ( 110 ), a weighting calculation unit ( 120 ) and an allocation unit ( 130 ). The bit counting unit ( 110 ) receives the memory ( 40 ) fail data from the memory test device ( 10 ).

3 exemplary shows the memory ( 40 ) concerned misinformation. The bit counting unit ( 110 ) may receive the miss data as a bit field as in 13 shown. The bit counting unit ( 110 ) may include a bit field memory storing the bit field. The example in 3 shown memory ( 40 ) has 10 address rows in each row and column. In addition, each point at which address rows intersect corresponds to a 1-bit memory cell. The miss bits in the memory ( 40 ) are indicated by an X. In the present example, the memory has ( 40 ) Miss bits at positions (1, 1), (1, 3), (1, 5), (1, 9), (2, 1), (3, 2), (3, 4), ( 3, 7), (5, 3), (6, 4) and (8, 4), wherein the first number stands for the row address and the second number for the column address.

For each fail bit included in a given fail row, for example row address rows 1, 2, 3, 5, 6, and 8, and column address rows 1, 2, 3, 4, 5, 7, and 9, counts the bit counting unit ( 110 ) the number of orthogonal fail bits, that is, the number of fail bits in a fail row containing the fail bit whose orientation deviates from that of the given fail row. For example, the number of orthogonal fail bits in a row address row n of the fail bit (n, m) is the number of fail bits in the column address row m that contains the fail bit (n, m) and is orthogonal to the one Row address row n. Where n and m are integers. The number of orthogonal fail bits in the column address row m of the fail bit (n, m) is the number of fail bits in the row address row n containing the fail bit (n, m) and orthogonal to the column address row m ,

More accurate Consider the number of orthogonal fail bits in the row address row 1 of the fail bit (1, 1) 2, that is the number of fail bits in the column address row 1. The number of orthogonal fail bits in the column address row 1 of the fail bit (1, 1) is 4. This is the number of fail bits in the row address row 1.

For each fail bit (m, n) counts the bit counting unit ( 110 ), the number of orthogonal fail bits in row address row n and the number of orthogonal fail bits in column address row m, and stores these two numbers for each fail bit. The bit counting unit ( 110 ) may include a row bit number register which stores the number of orthogonal fail bits in the row address row and a column bit number register which stores the number of orthogonal fail bits in the column address row for each bit of the column address row Memory ( 40 ).

The weighting calculation unit ( 120 ) calculates a weighting coefficient for each fail row of each fail bit based on the number of orthogonal fail bits of each fail bit in the fail row. For example, the weighting calculation unit ( 120 ) calculate the coefficient such that it is smaller for a fail bit having a large number of orthogonal fail bits. The weighting calculation unit ( 120 ) may calculate the weighting coefficient of a fail row to be equal to the sum of the weighting coefficients of the fail bits in the fail row.

More specifically, by sequentially arranging backup rows to fail rows having a larger number of fail bits, a larger number of fail bits can be repaired. However, since each memory cell of the memory ( 40 ) on a fixed surface of the memory ( 40 ), the memory cells are preferably formed as a two-dimensional matrix and have row address rows and column address rows. Therefore, each fail bit can be repaired by both the row address row and the column address row. In this situation, if both a row row backup row and a column address row backup row are located on the same fail bit, the number of fail bits that can be repaired will decrease.

Therefore, the backup row allocation device (FIG. 100 ) have a coefficient indicating whether each fail bit is to be repaired by a row address row or by a column address row by calculating the number of orthogonal fail bits in the row address row and in the column address row. Then, the weighting coefficient for assigning the backup rows for each fail bit can be obtained by calculating the sum of the coefficients of the fail bits in each fail row.

More specifically, the weighting calculation unit ( 120 ) calculate the weight coefficient of a fail row based on the sum of the reciprocal numbers of orthogonal fail bits of the fail bits in a fail row. For example, the numbers of orthogonal fail bits for the fail bits (1, 1) (1, 3) (1, 5) and (1, 9) in row address row 1 are 2, 2, 1, and 1, respectively Weighting unit ( 120 ) can calculate the weighting coefficient for row 1 to be the sum of the reciprocal numbers of these orthogonal fail bits, for example, the weighting coefficient can be calculated as 1/2 + 1/2 + 1/1 + 1 / 1 = 3. The weighting coefficient calculation unit ( 120 ) can calculate and store a weighting coefficient for each fail series. The weighting coefficient calculation unit ( 120 ) may include a weight register for each address row to store the weighting coefficient of the address row.

The allocation unit ( 130 ) determines which rows of failures the backup rows are to be assigned, based on the size of the weighting coefficients that are determined by the weighting calculation unit (FIG. 120 ) was calculated. For example, the allocation unit ( 130 Assign backup rows to those fail rows whose Ge weighting coefficients are greater. In the example of 3 the row address row 1 has the largest weighting coefficient, and thus the allocation unit ( 130 ) assigns a row-oriented backup row to row address row 1.

The allocation unit ( 130 ) can be determined in advance in terms of the number of column-oriented and row-oriented backup rows in the memory ( 40 ). For example, a user can assign the allocation unit ( 130 ) notify in advance regarding the number of backup rows. The allocation unit ( 130 ) may include an initial backup row number register which stores the number of row-oriented backup rows and the number of column-oriented backup rows corresponding to the notification. The allocation unit ( 130 ) may also include a remainder backup row number register which stores the number of remaining backup rows of each orientation, this number being calculated by subtracting from a backup row a determined orientation when a backup row is subtracting it Orientation is assigned to a fail row. The allocation unit ( 130 ) can assign a backup row to a determined orientation to a fail row, on the condition that the number of remaining backup rows of this orientation is not zero.

4 describes an exemplary method for the backup row allocation device ( 100 ). As in connection with 3 describes the allocation unit ( 130 ) of a properly oriented backup row of the fail row having the largest weighting coefficient, for example row address row 1 in FIG 3 , At that time, the allocation unit ( 130 ) the bit counting unit ( 110 ) inform you that a backup series has been assigned to a fail row.

The bit counting unit ( 110 ) calculates the number of orthogonal fail bits in the row and column of each fail bit, excluding those fail bits in a fail row to which backup rows have already been assigned. The bit counting unit ( 110 ) may also include an updated bit-field memory that stores a bit field of fail data from which fail bits are removed in fail-rows associated with backup rows.

The bit counting unit ( 110 ) of the present embodiment recalculates the number of orthogonal fail bits of each fail bit using the bit field as in FIG 4 in which the fail bits in row address row 1 have been repaired. The bit counting unit 110 may also include row-oriented and column-oriented recalculated bit-number registers that store the newly calculated number of orthogonal fail bits in the corresponding row and column for each fail bit.

The weighting calculation unit ( 120 ) calculates the weighting coefficient for each fail row, excluding those fail bits in fail rows associated with the backup rows, based on the new stored number of orthogonal fail bits given by the bit Counting unit ( 110 ) were recalculated. For example, the weighting coefficient in the row address row is 2 in 4 has been recalculated as ½ after the fail bits in row address row 1 have been repaired. The weighting calculation unit ( 120 ) recalculates and stores the weighting coefficient for each fail series. The weighting calculation unit ( 120 ) may additionally comprise for each address row an updated weight register which stores the weighting coefficient newly calculated for the corresponding address row.

The allocation unit ( 130 ) selects the next fail row to which a backup row is to be assigned, based on the new weighting coefficients to be allocated by the weighting calculation unit (FIG. 120 ) are stored. For example, the allocation unit ( 130 ) assign the next backup row to the fail row that has the largest updated weighting coefficient. Situations may occur in which different address rows have the same weighting coefficients, such as Row Address Row 3 and Column Address Row 4 in 4 , In such a case, the allocation unit prioritizes ( 130 ) a fail line with the guidance provided in advance by a user or the like when allocating backup rows. Instead, the allocation unit ( 130 ) prioritize the row of failures whose orientation corresponds to the orientation of a backup row having the greater remaining count when allocating the backup rows. As another example, the allocation unit ( 130 ) simultaneously assign backup rows to a plurality of fail rows having the same weighting coefficient.

By repeating the above-described method, the backup rows can be arranged so that the number of fail bits that can be repaired is maximized. Therefore, the backup row allocation device (FIG. 100 ) efficiently find a backup row allocation that is able to repair all fail bits.

5 shows another exemplary embodiment of the backup row allocation device tion ( 100 ). The backup row allocation device ( 100 ) of the present embodiment includes a repair possibility determination unit ( 140 ), in addition to the configuration of the backup row allocation device (FIG. 100 ), with reference to the 1 to 4 has been described. Other components of the backup row allocation device ( 100 ) of the present embodiment may be the same as the backup row allocation device (FIG. 100 ), in conjunction with the 1 - 4 has been described.

The repairability determination unit ( 140 ) determines whether all fail bits can be repaired by sequentially allocating the backup rows, as referenced in FIG 1 to 4 described. For example, the repair possibility determination unit (FIG. 140 ) every time the allocation unit ( 130 ) assigns a backup row to a fail row, determine if there is a possibility that all fail bits can be repaired.

For example, the repair possibility determination unit (FIG. 140 ) determine that there is no way to repair all fail bits when the number of remaining backup rows reaches zero while there are still unrepaired fail bits. Even if there are still remaining backup rows, the repair possibility determination unit (FIG. 140 ) determine whether there is a possibility that all fail bits can be repaired by using another method, such as that described below with reference to FIG 10 to 12 is described.

The allocation unit ( 130 ) the repair possibility determination unit ( 140 ) to which fail rows the backup rows have been assigned.

The repairability determination unit ( 140 ) can determine if there is a possibility that all fail bits will be repaired based on the content of the notification and the stored information in each memory and register in the bit counter ( 110 ), the weighting calculation unit ( 120 ) and the allocation unit ( 130 ).

For example, the repair possibility determination unit (FIG. 140 ) determine that there is no possibility to repair all fail bits if, as a result of the assignment of the backup rows to the fail rows, the number of stored rows in the remaining backup row number register of the allocation unit (FIG. 130 ) Reaches zero and the bit field stored in the updated bit field memory of the bit counter ( 110 ), contains fail data. As another example, the repair possibility determination unit (FIG. 140 ) determine that there is no way to repair all fail bits if, as a result of the allocation of the backup rows to the fail rows, the number of remaining backup rows reaches one of the orientations zero and the number of remaining backup rows the other orientation is less than the number of fail rows having this second orientation.

6 shows an exemplary method for the backup row allocation device ( 100 ) out 5 , In this example, fail bits are present at positions (1, 1), (1, 2), (2, 3), (2, 4), (2, 5), (2, 6), (3, 4), (3, 5) and (3, 6), wherein the first digit represents the row address and the second digit represents the column address. In addition, shows 6 a first state where a row-oriented backup row and four column-oriented backup rows remain. The first state off 6 can the initial state of the memory ( 40 ) or a step that has been reached after multiple backup rows in accordance with the reference to 1 to 5 described procedures have been assigned.

As with reference to the 1 to 4 described, calculates the weighting calculation unit ( 120 ) a weighting coefficient for each row of addresses. The allocation unit ( 130 ) assigns a backup row to the fail row, which has the largest weighting coefficient. In the example of 6 For example, row address row 2 has the largest weighting coefficient, and therefore, a row-oriented backup row is associated with row address row 2. As a result, the number of remaining row-oriented backup rows falls back to zero. In addition, the number of column-oriented fail rows becomes 5, which is larger than the four remaining column-oriented backup rows. In such a case, the repair possibility determination unit notifies ( 140 ) the allocation unit ( 130 ) that some of the fail bits can not be repaired.

Upon receipt of the notification, the allocation unit ( 130 ) the assignment of the backup row to the first fail row, which represents one of those fail rows to which a backup row has been assigned. In the example of 6 revokes the allocation unit ( 130 ) the assignment of the backup row to the first fail row, this is row address row 2, which was last assigned a backup row. At this time, the contents of each register and each memory in the bit counter ( 110 ), the weighting calculation unit ( 120 ) and the allocation unit ( 130 ) returned to the booth before assigning the backup row to the first fail row took place.

For example, in the case that the repair possibility determination unit ( 140 ) determines that some of the fail bits can not be repaired, the weighting calculation unit ( 120 ) recalculate the weighting coefficient such that it has the value that it had before the backup row was assigned to the first fail row. Instead, the bit counter ( 110 ), the weighting calculation unit ( 120 ) and the allocation unit ( 130 ) each include a cache memory which stores the state of each register and memory for each assignment of a backup line to a fail line.

In addition, the allocation unit ( 130 ) upon receipt of the notification by the repairability determination unit ( 140 ) that some of the fail bits can not be repaired, a second fail row for each fail bit in the first fail row, each of these second fail rows containing one of the fail bits in the first fail row and has an orientation that differs from the orientation of the first fail row, and allocates the backup rows to the selected second fail rows. In the example of 6 assigns the allocation unit ( 130 ) column-oriented backup rows to the four row-column address rows 3, 4, 5 and 6, which are address rows which are orthogonal to the row address row 2 and the fail bits (2, 3), (2, 4 ), (2, 5), (2, 6) of row address row 2.

Since the number of address rows selected as the second fail series is not larger than the number of remaining backup rows having the corresponding orientation, the repair possibility determination unit notifies (FIG. 140 ) the allocation unit ( 130 ) that there is a possibility that all fail bits can be repaired. The bit counting unit ( 110 ) and the weighting calculation unit ( 120 ) recalculate the fail data bit field, the number of orthogonal fail bits, the weighting coefficients, and the like, for the status resulting from the assignments of the backup rows to the second fail rows.

The allocation unit ( 130 ) selects the next fail row to which a backup row is to be assigned based on the newly calculated weighting coefficients. In the present example, the row address row 1 now has the largest weighting coefficient, so that the allocation unit ( 130 ) assigns a row-oriented backup row to row address row 1. At this time, the number of remaining row-oriented backup rows is not zero, and there are no fail bits after the assignment of the backup row, so that the repair possibility determination unit (FIG. 140 ) the allocation unit ( 130 ) can inform that this association allows all fail bits to be repaired. Upon receipt of this notification, the allocation unit ( 130 ) determines the status of the backup row assignment and notifies the setting unit ( 30 ).

As described above, the backup row allocation device (FIG. 100 ), if it is determined that setting a backup row to the first fail row results in thereafter no opportunity to repair all fail bits, revoking the assignment to the first fail row, such that a search for an appropriate backup row assignment with a backup set that has already been set to the first fail set, and any subsequent procedures will not be performed. As a result, the processing time can be reduced. In addition, the fail-bits in the first fail-row can not be repaired in case a backup-row has not been set for the first fail-row, if backup-rows have not been assigned to the orthogonal second fail-rows. If the assignment to the first fail-row has been revoked, as in the present example, the efficiency of searching for an appropriate back-up queue allocation can be increased by adding backup rows to the second fail-rows that are orthogonal to the first fail Rows are irrevocably assigned.

If the number of address rows selected as the second fail series is larger than the number of remaining backup rows having the corresponding orientation, the repair possibility determination unit notifies (FIG. 140 ) the allocation unit ( 130 ) that there is no possibility that all fail bits can be repaired. In such a case, there will be no allocation to backup rows, which will result in all fail bits, for that combination of remaining backup rows and remaining fail bits in the status, being repairable.

Therefore, the allocation unit ( 130 ) the assignment of a backup row to a fail row that was made just before the first status was reached. In other words, the allocation unit ( 130 ) the backup-row allocation, which resulted in the remaining fail-bits and remaining backup-rows reaching the first status. The allocation unit ( 130 ) then irrevocably allocates backup rows to those fail rows which contain the fail bits of the fail row whose association has been revoked and which is orthogonal to the fail row whose association has been revoked.

In this way, the backup row allocation device ( 100 ), in the event that there is no possibility that all fail bits can be repaired, sequentially revoke the backup rows assignments and irrevocably allocate backup rows to fail rows that are orthogonal to the fail rows, their associations were revoked. Thereafter, the backup row allocation device (FIG. 100 ), by searching for a suitable backup row allocation, efficiently determine an appropriate allocation.

7 FIG. 12 is a flowchart illustrating an exemplary operation of the backup row allocation device (FIG. 100 ) as related to the 1 to 6 described, visualized. First, as described above, the bit counting unit ( 110 ) the number of orthogonal fail bits in the row and column of each fail bit (S400).

Next, the weighting calculation unit calculates ( 120 ) the weighting coefficient of each fail line based on the number of orthogonal fail bits of the fail bits of each fail line (S402). The backup row allocation device ( 100 ) then asserts the backup row allocation based on the weighting coefficients of the fail rows, as related to 1 to 6 described (S404).

The backup row allocation device ( 100 ) then determines whether all fail bits can be repaired by the method S404 (S406). If all fail bits can be repaired, the setting unit ( 30 ) the repair procedure on the memory ( 40 ) before (S408). If some of the fail bits can not be repaired, the backup row allocation device (FIG. 100 ), a non-reparability method determined by a user or the like (S410).

8th FIG. 12 is a flowchart showing an example method corresponding to the allocation order allocation method (S404) as in FIG 7 described, visualized. As described above, the allocation unit ( 130 ) assigns a backup row to the fail row having the largest weighting coefficient (S500). Next, after the allocation unit ( 130 ) has made the assignment of a backup row to a fail row, the repairability determination unit determines ( 140 ), whether there is a possibility that all fail bits can be repaired based on a predetermined predetermined standard (S502). For example, the repair possibility determination unit (FIG. 140 ) determine whether there is a possibility that all fail bits can be repaired based on the remaining fail bits and the number of remaining backup rows, as described above.

If it is determined in (S502) that there is a possibility that all fail bits can be repaired, the data in each register and memory in the bit counter ( 110 ) and the weighting calculation unit ( 120 ) updated. For example, the weighting calculation unit updates ( 120 ) the weighting coefficients (S504). The repairability determination unit ( 140 ) then determines if there are fail bits that have not been repaired (S506). If it is determined (S506) that there are fail bits that have not been repaired, the procedure is repeated beginning at (S500), sequentially allocating the backup rows. If it is determined (S506) that there are no fail bits that have not been repaired, it is determined that this backup row allocation can repair all fail bits. (S508). In this case, the setting unit ( 30 ) the repair procedure (S508) as in 7 described, out.

If it is determined at (S502) that there is no possibility that all fail bits can be repaired, the allocation unit (FIG. 130 ) the backup row allocation made immediately before (S510). The data in each register and memory in the bit counter ( 110 ) and the weighting calculation unit ( 120 ) is then reset to the state the data had before this backup row assignment was made. For example, the weighting calculation unit ( 120 ) recalculate the weighting coefficients for the status just before the backup row assignment.

Next, the allocation unit ( 130 ) second fail-rows containing the fail-bits of the first fail-row of their backup-row assignment and arranged orthogonal to the first fail-row, and allocating backup-rows to the selected second fail-rows ( S514). The repairability determination unit ( 140 ) then determines if there is a possibility that all fail bits can be repaired (S516).

If it is determined at (S516) that there is a possibility that all fail bits can be repaired, the processes of (S504) are further executed based on the current backup row allocation. If it is determined at (S516) that some of the fail bits can not be repaired, the allocation unit (FIG. 130 ) determine whether a previously made backup row assignment can be revoked (S518). For example, the allocation unit ( 130 ) determine that an earlier backup row assignment will not be revoked can, if all backup row assignments have already been revoked, 40 ) back to its initial status.

If it is determined at (S518) that a previous backup row allocation can be revoked, the process returns to (S510) and the allocation unit (FIG. 130 ) revokes the backup row assignment performed immediately before. If it has been determined at S518 that a previous backup row allocation can not be revoked, then there is no possible backup row allocation which includes all fail bits in the storage (FIG. 40 ) so that the procedure ends. In such a case, the non-reparability method (S410) is executed as in 7 described. With the above methods, the backup row allocation device (FIG. 100 ) efficiently determine a suitable backup row allocation.

In the above examples, the weighting coefficient is updated for every fail row each time a backup row is allocated, however, it is not necessary for the backup row allocation apparatus (FIG. 100 ) updates the weighting coefficient of each fail row. In such a case, the backup row allocation device (FIG. 100 ) refrain from the weighting coefficient updating process (S5049 and the weighting coefficient recalculation method (S512) from the process flowchart shown in FIG 8th visualized, execute. This process flow also allows the backup row allocation device ( 100 ) also to efficiently determine a suitable backup row allocation.

In addition, the last backup row allocation is revoked (S512) if (S502) determines that not all the fail bits can be repaired, as can be seen in the example method 8th , Instead, the method (S512) may initiate the revocation of the first backup row allocation performed at (S500). In such a case, the process (S512) executes each register and each memory in the bit counter ( 110 ) and the weighting calculation unit ( 120 ) back to the initial status. In addition, the allocation unit ( 130 ) prior to the process of (S500), pre-allocating the backup rows to the fail series containing a predetermined number of fail bits.

9 shows another example of fail data in memory ( 40 ). The memory region of this memory ( 40 ) is divided into a plurality of memory blocks, in at least one row direction and one column direction. In the example off 9 is the memory region of the memory ( 40 ) in three blocks in the row direction and in two blocks in the column direction. The memory ( 40 ) may have row-oriented and column-oriented backup rows for each memory block.

If the method of step (S502), as in 8th shown on this memory ( 40 ) and the repairability determination unit ( 140 ) determines that some of the fail bits can not be repaired, the immediate assignment of the backup row to a first fail row is revoked (S510). In (S514), the assignment unit ( 130 ) third fail rows in each memory block which have the same orientation as the first fail row and which contain the same number of fail bits as the first fail row, and irrevocably allocate backup rows to the selected third fail Rows too. At this time, the allocation unit ( 130 Assign backup rows to both the second fail rows described above and the third fail rows.

For example, the following describes a situation in which a backup row is added to the row address row 1 that is in 9 is assigned in accordance with the method of (S500) which is shown in 8th will be shown. In this situation, if it is determined that some of the fail bits can not be repaired (S502), the row address rows 1, 2, 7, 8 and 9 are selected as the second fail series, in accordance with the method of (S514) , Moreover, the number of fail bits included in the row address row 2 in each memory block is the same as the number of fail bits included in the row address row 1 in each memory block, and therefore, the allocating unit (FIG. 130 ), the third fail series are such that they are the column address rows 2, 3, 6, 7 and 9, which contain the fail bits from the row address rows 2 and are orthogonal to the row address rows 2.

The allocation unit ( 130 ) then irrevocably allocates backup rows to the selected second and third fail rows (S514). Thus, if backup rows are provided to each of the memory blocks, if all of the fail bits can not be repaired as a result of assigning the backup rows to a determined fail set, then the chances of the fail bits failing are high. Row, which contains the same number of fail bits per block of memory as the determined fail row, are also unrecoverable when a backup row is assigned to this fail row. By assigning irrevocable backup rows to the third fail rows that are orthogonal to that fail row, the search for suitable backup row mappings can be performed even more efficiently.

10 shows another exemplary embodiment of the backup row allocation device (FIG. 100 ). The backup row allocation device ( 100 ) of the present embodiment includes an isolated fail detection unit ( 150 ), in addition to the configuration of the backup row allocation device (FIG. 100 ) as they relate to 5 is described. Other components of the backup row allocation device ( 100 ) of the present embodiment may be the same as those of the backup row allocation device (FIG. 100 ) as they relate to 5 is described.

If a detected fail bit has no further fail bits in the same row and no further fail bits in the same column, the isolated fail detection unit determines ( 150 ) this fail bit as an isolated fail bit. In other words, if there is only one fail bit in a determined column-oriented fail-row and there are no more fail-bits in the row-oriented fail-row containing that fail bit and orthogonal to this determined fail-row, Determines the isolated fail detection unit ( 150 ) that this fail bit is an isolated fail bit. The isolated fail detection unit ( 150 ) may determine sequentially isolated fail bits for each state of the bit field based on the fail data bit field which is sequentially updated and output by the bit counter ( 110 ) is stored.

11 shows an exemplary fail data bit field corresponding to the isolated fail detection unit (FIG. 150 ) provided. As described above, the isolated fail detection unit ( 150 ) determine the isolated fail bits based on this bit field. In the present example, the isolated fail determination unit determines ( 150 ) five isolated fail bits at positions (1, 1), (2, 2), (3, 3), (4, 4) and (5, 5).

During the procedures of (S502) and (S516) in 8th the repairability determination unit ( 140 ) determine if there is a possibility that all fail bits can be repaired based on the number of isolated fail bits and the number of remaining backup rows. For example, the repair possibility determination unit (FIG. 140 ) determine that there is no way to repair all fail bits if the sum of the number of row-oriented backup rows and the number of column-oriented backup rows is less than the number of isolated fail bits.

During the process from (S500) in 8th can the allocation unit ( 130 ) select the fail row to which a backup row should be irrevocably assigned, based on the number of isolated fail bits and the number of remaining backup rows. For example, the allocation unit ( 130 ) to rank the fail rows of each orientation containing an isolated fail bit, a number of row-oriented backup rows obtained as the result of subtracting the number of remaining column-oriented backup rows from the number of isolated fail bits becomes.

For example, if there are five isolated fail bits and two remaining column-oriented backup rows, the allocation unit ( 130 ) three row-oriented backup rows to each of the three row-oriented fail rows containing an isolated fail bit. In the same way, if there are five isolated fail bits and four remaining row-oriented backup rows, the allocation unit ( 130 ) to a column-oriented backup row to any column-oriented fail-row containing an isolated fail bit.

Of the maximum value of the number of isolated fail bits that are backed up by backup rows any orientation can be repaired, is the same the number of remaining backup rows of the corresponding ones Orientation. Therefore, in the event that the number of remaining backup rows "a", which is a row orientation or a column orientation is less than the number On isolated fail bits "b", at least "b-a" must have isolated fail bits where backup batches are used, which are have the other orientation.

Accordingly, as described above, the backup row allocation device (FIG. 100 ) search for a suitable backup row orientation by irrevocably allocating the backup rows based on the number of isolated fail bits and the number of remaining backup rows. In addition, the isolated fail-detection unit ( 150 ) determine those isolated fail bits for each state of a bit field from which the fail-rows of the fail-rows are removed, each time the allocation unit ( 130 ) assigns a backup row to a fail row based on the weighting coefficients. The isolated fail-detection unit ( 150 ) may contain a register which stores the isolated fail bits in each state.

If all fail bits that are still to be repaired are isolated fail bits and not all backup rows have been allocated, it is determined that all fail bits are repairable if the number of isolated fail bits is less than the number on remaining backup rows. In such a case, the allocation unit ( 130 ) assign the backup rows to all remaining fail rows and then the End the assignment procedure. For example, the allocation unit ( 130 ) Prioritize backup rows with a previously determined orientation by a user or the like and assign backup rows to the remaining fail rows in accordance with this prioritization.

The procedures associated with the isolated fail bits as with reference to FIG 10 and 11 can be performed for each memory block as described with reference to 9 described. For example, the repair capability determination unit ( 140 ) determine that there is no possibility that all fail bits can be repaired if the sum of the remaining row-oriented backup rows and the remaining column-oriented backup rows is less than the number of isolated fail bits in any of the memory blocks.

12 shows an exemplary embodiment of a part of the repair possibility determination unit ( 140 ). The repairability determination unit ( 140 ) of the present embodiment, a first multiplying unit ( 142 ), a second multiplier unit ( 144 ), and a comparison unit ( 146 ) in addition to the design necessary for the execution of the functions related to the 1 - 11 are required.

The first multiplication unit ( 142 ) calculates a first multiplied value in which the maximum number of fail bits contained in a column-oriented fail row multiplied by the number of remaining column-oriented backup rows. In other words, the first multiplied value denotes the maximum number of fail bits that can be repaired by the remaining column-oriented backup rows. The second multiplication unit ( 144 ) calculates a second multiplied value in which the maximum number of fail bits contained in a row-oriented fail row multiplied by the number of remaining row-oriented backup rows. In other words, the second multiplied value denotes the maximum number of fail bits that can be repaired by the remaining row-oriented backup rows.

The comparison unit ( 146 ) determines whether the sum of the first multiplied value and the second multiplied value is smaller than the total number of remaining fail bits. If the sum of the first multiplied value and the second multiplied value is less than the total number of remaining fail bits, not all fail bits can be repaired by the remaining backup rows. In such a case, the comparison unit notifies ( 146 ) the allocation unit ( 130 ) about this circumstance.

13 shows an exemplary bit field of fail bits. The total number of fail bits in this bit field is 13, leaving three row-oriented backup rows and three column-oriented backup rows.

The first multiplication unit ( 142 ) determines the maximum number of fail bits contained in a row-oriented fail row. As in 13 shown, the maximum number of fail bits in a row is two. The first multiplication unit ( 142 ) calculates the first multiplied value by multiplying the maximum number of fail bits by the number of remaining backup rows, for example 2 × 3 = 6.

In the same way, the second multiplier unit determines ( 144 ) the maximum number of fail bits contained in a column-oriented fail row. As in 13 shown, the maximum number of fail bits in a column is two. The second multiplication unit ( 144 ) calculates the second multiplied value by multiplying the maximum number of fail bits by the number of remaining backup rows, for example 2 × 3 = 6.

As a result, the sum of the first multiplied value and the second multiplied value is 12 in the present example, which is less than the 13 remaining fail bits. Therefore, the comparison unit ( 146 ) the allocation unit ( 130 ) that not all fail bits can be repaired. With this method, the row allocation device ( 100 ) can determine much faster that there is no way to repair all fail bits and therefore can more efficiently search for a suitable backup row allocation.

The repair facility determination unit ( 140 ) can perform the method by using the first and second multiplied values as referenced in FIG 12 and 13 described for each of the memory blocks, as with reference to the 9 is described. For example, if the sum of the first multiplied value and the second multiplied value is smaller than the number of remaining fail bits in one of the memory blocks, the repair possibility determination unit (FIG. 140 ) determine that there is no way to repair all fail bits.

14 FIG. 12 shows a flow chart describing an exemplary memory manufacturing method, in accordance with an embodiment of the present invention. FIG. The memory manufacturing method uses the backup-row allocation method and the memory-repair method driving, which with respect to the 1 to 13 are described to the memory ( 40 ) For example, produce a semiconductor memory.

Ms First, during memory fabrication becomes a memory ( 40 ), which contains a large number of backup series (S600). Next, the memory ( 40 ) to pass fail data to the memory ( 40 ) (S602).

Next, during the backup row allocation, a determination is made to which fail rows to assign to backup rows, from the set of row-oriented fail rows and column-oriented fail rows, the fail bits in the memory ( 40 ) (S604). The process of (S604) is performed using the backup row allocation device (FIG. 100 ) referring to the 1 to 13 is described.

A non-defective memory ( 40 ) is then made by specifying the fixed backup row allocation in memory ( 40 ) is converted to the memory ( 40 ) (S606). The method of S606 may be performed by having the setting unit ( 30 ) used with reference to the 1 to 13 is described. With this method, a non-defective memory ( 40 ) are produced efficiently.

15 shows an example of a hardware configuration of a computer ( 1900 ) according to the present embodiment. The computer ( 1900 ) can be used as the backup row allocation device ( 100 ), as related to the 1 to 14 described based on a program which is provided to this.

If the computer ( 1900 ) as a backup row allocation device ( 100 ), the program can use the computer ( 1900 ), at least acting as one of the devices, such as the bit counting unit ( 110 ), the weighting calculation unit ( 120 ), the allocation unit ( 130 ), the repair possibility determination unit ( 140 ) and the isolated fail determination unit ( 150 ), as related to the 1 to 14 described. For example, the program can use a CPU ( 2000 ) than the bit counter ( 110 ) the weighting calculation unit ( 120 ), the allocation unit ( 130 ), the repair possibility determination unit ( 140 ), and the isolated fail-detection unit ( 150 ) and can be a hard drive ( 2040 ) or a RAM ( 2020 ), as each register and memory in the bit counter ( 110 ), the weighting calculation unit ( 120 ), and the allocation unit ( 130 ) to act.

In accordance with the present embodiment, the computer ( 1900 ) equipped with a CPU peripheral, which a CPU ( 2000 ) contains a RAM ( 2020 ), a graphics controller ( 2075 ) and a display device ( 2080 ), all with each other via a host controller ( 2082 ) are connected; an input / output element which the communication interface ( 2030 ), the hard disk ( 2040 ), and a CD-ROM drive ( 2060 ), all with the host controller ( 2082 ) via an input / output controller ( 2084 ) are connected; and a legacy input / output unit containing a ROM ( 2010 ), a mobile drive ( 2050 ), and an input / output chip ( 2070 ), all with the input / output controller ( 2084 ) are connected.

The host controller ( 2082 ) is with the RAM ( 2020 ) and is also connected to the CPU ( 2000 ) and the graphic controller ( 2075 ), whereby the RAM ( 2020 ) can be addressed with a high transfer rate. The CPU ( 2000 ) controls each unit based on programs stored in the ROM ( 2010 ) and the RAM ( 2020 ) are stored. The graphics controller ( 2075 ) obtains image data from the CPU ( 2000 ) or the like on a frame buffer within the RAM ( 2020 ) and visualizes the image data in the display device ( 2080 ). Instead, the graphics controller ( 2075 ) contain the image buffer internally, which contains the image files generated by the CPU ( 2000 ) or similar, stores.

The input / output controller ( 2084 ) connects the communication interface ( 2030 ), which serves as a relative high-speed input / output device, the hard disk ( 2040 ) and the CD-ROM drive ( 2060 ) with the host controller ( 2082 ). The communication interface ( 2030 ) communicates with other devices over a network. For example, the communication interface ( 2030 ) the communication between the memory test device ( 10 ) and the setting unit ( 30 ) enable. The hard disk ( 2040 ) stores the programs and data sent by the CPU ( 2000 ), which are in the computer ( 1900 ) is located. The CD-ROM drive ( 2060 ) reads the programs and data from a CD-ROM ( 2095 ) and puts the read information about the RAM ( 2020 ) of the hard disk ( 2040 ) to disposal.

In addition, the input / output controller ( 2084 ) with the ROM ( 2010 ) and is also connected to the mobile drive ( 2050 ) and the input / output chip ( 2070 ), which serves as a relatively fast input / output device. The ROM ( 2010 ) stores a startup program which will be executed as soon as the computer ( 1900 ) is turned on; a program, which on the hardware of the computer ( 1900 ) and similar. The mobile drive ( 2050 ) reads programs or data from a mobile data carrier ( 2090 ) and puts the read information about the RAM ( 2020 ) of the hard disk ( 2040 ) to disposal. The input / output chip ( 2070 ) connects the mobile drive ( 2050 to each of the input / output devices via, for example, a parallel port, a serial port, a keyboard port, a mouse port, or the like.

The programs that use the hard disk ( 2040 ) over the RAM ( 2020 ) are stored on a storage medium, such as a mobile data carrier ( 2090 ) a CD-ROM ( 2095 ) or an IC card and are provided by a user. The programs are read from the storage medium via the RAM ( 2020 ) on the hard disk ( 2040 ), which are in the computer ( 1900 ) and installed by the CPU ( 2000 ).

The programs are stored in the computer ( 1900 ) Installed. These programs require the CPU ( 2000 ) or something similar to the fact that the computer ( 1900 ) as each unit of the backup row allocation device (FIG. 100 ), as described above.

The programs and modules described above can also be stored on an external storage medium. The mobile data carrier ( 2090 ), the CD-ROM ( 2095 ), an optical storage medium such as a DVD or CD, a magneto-optical storage medium, a tape medium, a semiconductor memory such as an IC card or the like can be used as a storage medium. In addition, a storage device such as a hard disk or a RAM equipped with a server system and connected to the Internet or a specialized communication network can be used to send the programs to the computer. 1900 ) via a network.

Even though the embodiments of the present invention have been described, the technical scope is not on the above limited embodiments described. The expert It is obvious that various changes and improvements can be added to the embodiments described above. It is also evident from the claims that the configurations to which such changes or Improvements are added in technical teaching may be included in the invention.

As described above, the backup row allocation device (FIG. 100 ) of the present invention efficiently search for a suitable backup row allocation. In addition, the memory repair device ( 20 ) efficiently repair the memory.

Summary

stated becomes a backup row allocation device that determines which Fail rows in a store with a variety of backup rows Backup rows to be assigned, comprising a bit counting unit, for each fail bit contained in each fail row is counting the number of orthogonal fail bits that is the number of fail bits in a fail row, each fail bit contains and has an orientation that depends on the orientation differs each fail-row, and storing the number of orthogonal ones Fail bits associated with each fail bit; a Weight calculation unit that calculates a weighting coefficient for each fail row, based on the number of orthogonal ones Fail bits of the fail bits included in each fail row and storing the weight of each fail series; and an allocation unit, which determines which of the fail rows to allocate backup rows are based on the relative size of the weighting coefficients, calculated by the weighting calculation unit.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - JP 2-24899 [0003]

Claims (18)

Backup row allocator that detects which fail series from the row-oriented fail series and the column-oriented fail-rows contain fail bits in a memory with a variety of backup rows to the backup rows this assign, comprising: a bit calculation unit used for each fail bit contained in each fail row, one Number of orthogonal fail bits that counts a number represents fail bits in a fail row containing each fail bit and having an orientation different from the orientation of each fail row and stores the number of orthogonal fail bits that associated with each fail bit; a weighting calculation unit, for each fail row, a weighting coefficient calculated based on the number of orthogonal fail bits of the Fail bits included in each fail row and the weighting coefficient stores associated with each fail series; and a Commitment unit that determines to which fail rows the backup rows should be assigned based on the relative size the weighting coefficients determined by the weighting calculation unit were calculated. A backup row allocation device according to claim 1, characterized in that the bit counting unit for each of the fail bits is the number of orthogonal fail bits for the associated row-oriented fail-row and for the associated column-oriented fail row counts. A backup row allocation device according to claim 2, characterized in that the weighting calculation unit calculated the weighting coefficient for each fail row based on on the sum of the reciprocal numbers of orthogonal fail bits the fail bits included in each fail row. A backup row allocation device according to claim 2, characterized in that the allocation unit a backup series to one of the fail series based on the weighting coefficients, the Weighting Calculation Unit The Weighting Coefficient for Each fail row calculates failing bits that fail in rows which backup rows are assigned excludes, and stores each new weighting coefficient associated with the corresponding fail series is linked, and the Allocation unit selects the next fail series, to which a backup series should be assigned, based on the new weighting coefficients stored by the weighting calculation unit were. A backup row allocation device according to claim 4, characterized in that the allocation unit is a sequential Allocating the backup rows to the fail rows, which are the largest Have weighting coefficients, the backup row allocation device In addition, a repairability detection unit which determines whether each of the fail bits will be repaired thereby can be that the backup rows are sequential to the respective Fail rows are assigned, which are the largest Have weighting coefficients and if the repairability-determining element detects that some of the fail bits can not be repaired, the allocation unit (i) the assignment of the backup rows to a first fail row, which is a fail row already a backup row was assigned, (ii) selects second fail rows, each containing a fail bit, which in the first fail row is included, and which have an orientation of the Orientation of the first fail row differs, and (iii) backup rows too assigns to the second fail series. A backup row allocation device according to claim 5, characterized in that if the repair possibility recognition unit determines that some of the fail bits can not be repaired, the weighting calculation unit, the weighting coefficients recalculated such that the weighting coefficients are the value they had before assigning the backup rows to the first fail row was done. A backup row allocation device according to claim 6, characterized in that each time the allocation unit assigning a backup row to a fail row, the repair capability detection unit determines if there is a possibility that all fail rows can be repaired based on a previously determined Determination standard, and if the repair possibility recognition unit determines that there is no possibility that all fail bits can be repaired, the allocation unit the assignment the backup series picks up the first fail series, the most recent one Fail row to which a backup row has been assigned. A backup row allocation apparatus according to claim 6, characterized in that each time said allocation unit assigns a backup row to a fail row, the repair possibility recognition unit determines whether there is a possibility that all fail rows can be repaired, based on a pre-determined determination standard, and if the repair possibility recognition unit determines that there is no possibility that all fail bits can be repaired, the allocation unit allocates Cancel backup row to the first fail row, which is the one fail row to which a backup row was first assigned. A backup row allocation device according to claim 5, characterized in that a memory area of the memory is divided into a variety of memory blocks, from which arranged at least one in the column direction and one in the row direction is, and the memory backup rows for each memory block contains, and if the repair capability detection unit determines that some of the fail bits can not be repaired, the allocation unit also has backup rows to the Assigning fail series that have the same orientation as the first fail row and the same number of fail bits in each memory block like the first fail row. A backup row allocation device according to claim 1, characterized in that the allocation unit, the backup rows assigns the fail series in advance, which is a pre-determined number included in fail bits. A backup row allocation device according to claim 1, further comprising an isolated fail detection unit which, if both the row-oriented fail-row and the column-oriented fail row of a fail bit no further fail bits where the fail bit recognizes as an isolated fail bit, where the Allocation unit a number of row-oriented backup rows assigns to those fail rows containing isolated fail bits, where the number of associated row-oriented backup rows corresponds to the result obtained by subtraction the number of column-oriented backup rows that are not among the Fail rows have been assigned from the number of isolated fail bits and the allocation unit has a number of column-oriented ones Backup rows to those fail rows the isolated fail bits contain, assigns the number of associated column-oriented Backup rows equals the result obtained by Subtraction of the number of column-oriented backup rows, the not to the fail series of the number of isolated fail bits have been assigned. A backup row allocation device according to claim 11, characterized in that each time the allocation unit assigns a backup row to a fail row, the isolated fail detection unit recognizes the isolated fail bits, failing those bits Excludes fail rows associated with backup rows. A backup row allocation device according to claim 11, characterized in that if all those fail bits, which have not been assigned a backup row, are isolated fail bits, the allocation unit prioritizes backup series, which is a pre-determined Orientation, and the backup rows follow the fail rows Assigns to this prioritization. A backup row allocation device according to claim 9, characterized in that the repair possibility determining element includes: a first multiplying unit for each Memory block calculates a first multiplication value by they (i) a maximum number of fail bits that are in a column-oriented Fail row are included, multiplied by (ii) the number of Backup rows that have not yet been assigned to a fail row the column-oriented backup rows associated with each memory block linked; a second multiplier unit, the for each memory block, a second multiplication value in which it calculates (iii) a maximum number of fail bits in a row-oriented fail row are multiplied with (iv) the number of backup rows that are not yet fail-rows from the row-oriented backup series, the associated with each memory block; and a comparison unit, which determines for each memory block whether the sum of the first multiplied value and the second multiplied value Value is less than the total number of fail bits that are in each memory block and if it has been determined that the sum of the multiplied Values is less than the total number of fail bits in each the memory blocks is determined that not all fail bits are repaired can be. A memory repair apparatus that repairs fail bits of a memory containing a plurality of backup rows, comprising: a backup row allocator that determines which fail series from the row oriented fail rows and the column oriented fail rows Contain fail bits in memory to allocate them to the backup rows; and a setting unit that determines the allocation determined by the backup row allocation device in the memory, the backup row allocation device comprising: a bit count unit corresponding to each fail bit generated in each fail series counts a number of orthogonal fail bits representing a number of fail bits in a fail row containing each fail bit and having an orientation that deviates from the orientation of each fail row, and the Stores number of orthogonal fail bits associated with each fail bit; a weighting calculation unit that calculates a weighting coefficient for each fail row based on the number of orthogonal ones Fail bits of the respective fail bits included in each fail series and storing the weighting coefficients associated with each fail series; and an allocation unit that determines which of the fail rows should be assigned backup rows based on the relative size of the weighting coefficients calculated by the weighting calculation unit. Backup row allocation method for determining which fail series from the row-oriented fail rows and column-oriented ones Fail-series fail-bits contained in a memory containing a variety Contains backup rows to assign backup rows to them. full: for each fail bit, which in each fail row calculating a number of orthogonal fail bits, which corresponds to a number of fail bits in a fail row, the contains every fail bit and has an orientation, which differs from the orientation of each fail series, and save the number of orthogonal fail bits associated with each fail bit are; Calculating a weighting coefficient for each fail row based on the number of orthogonal fail bits those fail bits contained in each fail row, and Saving the weighting coefficient, with each fail row linked; and Determine which Fail Ranks Backup rows should be assigned based on the relative size the weighting coefficients. Memory manufacturing process for the production of Save, comprising: Manufacture of the store with a variety at backup rows; and Repair the memory by detecting, which fail series from the row-oriented fail series and the column-oriented fail-series fail bits in the fabricated memory to allocate the backup rows to this, with the fixing of the memory comprises: for each fail bit, which Included in each fail series is counting a number orthogonal fail bits, which is the number of fail bits in a fail row, which contains every fail bit and has an orientation, which differs from the orientation of each fail series, and save the number of orthogonal fail bits associated with each fail bit; To calculate a weighting coefficient based on each fail series on the number of orthogonal fail bits of those fail bits that are included in each fail row and storing the weighting coefficient, associated with each fail series; and Determine, which rows of failures should be assigned to backup rows on the relative size of the weighting coefficients. Program that enables a computer to act as a backup row allocation device that determines which fail series from the row-oriented fail rows and the column-oriented ones Fail-series fail-bits contained in a memory containing a variety Contains backup rows to assign backup rows to them. the program enables the computer to act as: a Bit counter, which for each fail bit, which in each fail row, a number of orthogonal fail bits counts, this is a number of fail bits in a fail row, which contains every fail bit and has an orientation, which differs from the orientation of each fail series, and the number stores at orthogonal fail bits associated with each fail bit are; a weighting calculation unit having a weighting coefficient calculated for each fail row based on number on orthogonal fail bits of those fail bits contained in each fail row are, and the weighting coefficient that stores with each Fail series is linked; and an allocation unit, which determines which rows of fail are assigned to backup rows based on the relative size of the Weighting coefficients generated by the weighting calculation unit were calculated.